Nichia STS-DA1-0756A <Cat.No > SPECIFICATIONS FOR NICHIA CHIP TYPE UV LED MODEL : NSSU100BT NICHIA CORPORATION -0-
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1 SPECIFICATIONS FOR NICHIA CHIP TYPE UV LED MODEL : NSSU100BT NICHIA CORPORATION -0-
2 1.SPECIFICATIONS (1) Absolute Maximum Ratings (Ta=25 C) Item Symbol Absolute Maximum Rating Unit Forward Current IF 25 ma Pulse Forward Current IFP 80 ma Allowable Reverse Current IR 85 ma Power Dissipation PD 100 mw Operating Temperature Topr -30 ~ + 85 C Storage Temperature Tstg -40 ~ +100 C Soldering Temperature Tsld Reflow Soldering : 260 C for 10sec. Hand Soldering : 350 C for 3sec. IFP Conditions : Pulse Width 10msec. and Duty 1/10 (2) Initial Electrical/Optical Characteristics (Ta=25 C) Item Symbol Condition Min. Typ. Max. Unit Forward Voltage VF IF=20[mA] - (3.6) 4.0 V Peak Wavelength Rank Ub λp IF=20[mA] nm Spectrum Half Width λ IF=20[mA] - (15) - nm Rank 6 φe IF=20[mA] µw Radiant flux Rank 7 φe IF=20[mA] µw Rank 8 φe IF=20[mA] µw Radiant flux Values are traceable to the CIE 127:2007-compliant national standards. Radiant flux Measurement allowance is ±10%. Peak Wavelength Measurement allowance is ±3nm. Basically, a shipment shall consist of the LEDs of a combination of the above ranks. The percentage of each rank in the shipment shall be determined by Nichia. 2.INITIAL OPTICAL/ELECTRICAL CHARACTERISTICS Please refer to CHARACTERISTICS on the following pages. 3.OUTLINE DIMENSIONS AND MATERIALS Please refer to OUTLINE DIMENSIONS on the following page. 4.PACKAGING The LEDs are packed in cardboard boxes after taping. Please refer to TAPING DIMENSIONS and PACKING on the following pages. The label on the minimum packing unit shows ; Part Number, Lot Number, Ranking, Quantity In order to protect the LEDs from mechanical shock, we pack them in cardboard boxes for transportation. The LEDs may be damaged if the boxes are dropped or receive a strong impact against them, so precautions must be taken to prevent any damage. The boxes are not water resistant and therefore must be kept away from water and moisture. When the LEDs are transported, we recommend that you use the same packing method as Nichia. -1-
3 5.LOT NUMBER The first six digits number shows lot number. The lot number is composed of the following characters; - - Year ( 8 for 2008, 9 for 2009 ) - Month ( 1 for Jan., 9 for Sep., A for Oct., B for Nov. ) - Nichia's Product Number - Ranking by Wavelength, Ranking by Radiant flux -2-
4 6.RELIABILITY (1) TEST ITEMS AND RESULTS Test Item Standard Test Method Test Conditions Note Number of Damaged Resistance to Soldering Heat (Reflow Soldering) JEITA ED Tsld=260 C, 10sec. (Pre treatment 30 C,70%,168hrs.) 2 times 0/50 Solderability JEITA ED-4701 Tsld=245 ± 5 C, 5sec. 1 time 0/50 (Reflow Soldering) A using flux over 95% Lead-free Solder (Sn-3.0Ag-0.5Cu) Temperature Cycle JEITA ED C ~ 25 C ~ 100 C ~ 25 C 100 cycles 0/ min. 5min. 30min. 5min. Moisture Resistance Cyclic JEITA ED C ~ 65 C ~ -10 C 10 cycles 0/ %RH 24hrs./1cycle High Temperature Storage JEITA ED-4701 Ta=100 C 1000 hrs. 0/ Temperature Humidity JEITA ED-4701 Ta=60 C, RH=90% 1000 hrs. 0/50 Storage Low Temperature Storage JEITA ED-4701 Ta=-40 C 1000 hrs. 0/ Steady State Operating Life Ta=25 C, IF=25mA 1000 hrs. 0/50 Steady State Operating Life of High Temperature Steady State Operating Life of High Humidity Heat Steady State Operating Life of Low Temperature Vibration JEITA ED Ta=85 C, IF=7.5mA 1000 hrs. 0/50 60 C, RH=90%, IF=20mA 500 hrs. 0/50 Ta=-30 C, IF=20mA 1000 hrs. 0/ ~ 2000 ~ 100Hz Sweep 4min. 200m/s 2 3directions, 4cycles 48min. 0/50 Substrate Bending JEITA ED mm, 5 ± 1 sec. 1 time 0/50 Adhesion Strength JEITA ED N, 10 ± 1 sec. 1 time 0/50 (2) CRITERIA FOR JUDGING DAMAGE Criteria for Judgement Item Symbol Test Conditions Min. Max. Forward Voltage VF IF=20mA - U.S.L.*) 1.1 Radiant flux φe IF=20mA L.S.L.**) *) U.S.L. : Upper Standard Level **) L.S.L. : Lower Standard Level -3-
5 7.CAUTIONS (1) Cautions The devices are UV light LEDs. The LED during operation radiates intense UV light, which precautions must be taken to prevent looking directly at the UV light with unaided eyes. Do not look directly into the UV light or look through the optical system. When there is a possibility to receive the reflection of light, protect by using the UV light protective glasses so that light should not catch one s eye directly. The caution label is attached to cardboard box. LED 放射光学測定装置で直接観察してはならないクラス 1M LED 製品 UV LED LED RADIATION DO NOT VIEW DIRECTLY WITH OPTICAL INSTRUMENTS CLASS 1M LED PRODUCT (2) Moisture Proof Package When moisture is absorbed into the SMT package it may vaporize and expand during soldering. There is a possibility that this can cause exfoliation of the contacts and damage to the optical characteristics of the LEDs. For this reason, the moisture proof package is used to keep moisture to a minimum in the package. The moisture proof package is made of an aluminum moisture proof bag. A package of a moisture absorbent material (silica gel) is inserted into the aluminum moisture proof bag. The silica gel changes its color from blue to pink as it absorbs moisture. (3) Storage Storage Conditions Before opening the package : The LEDs should be kept at 30 C or less and 90%RH or less. The LEDs should be used within a year. When storing the LEDs, moisture proof packaging with absorbent material (silica gel) is recommended. After opening the package : The LEDs should be kept at 30 C or less and 70%RH or less. The LEDs should be soldered within 168 hours (7days) after opening the package. If unused LEDs remain, they should be stored in moisture proof packages, such as sealed containers with packages of moisture absorbent material (silica gel). It is also recommended to return the LEDs to the original moisture proof bag and to reseal the moisture proof bag again. If the moisture absorbent material (silica gel) has faded away or the LEDs have exceeded the storage time, baking treatment should be performed using the following conditions. Baking treatment : more than 24 hours at 65 ± 5 C Nichia LED electrodes are gold plated. The gold surface may be affected by environments which contain corrosive substances. Please avoid conditions which may cause the LED to corrode, tarnish or discolor. This corrosion or discoloration may cause difficulty during soldering operations. It is recommended that the customer use the LEDs as soon as possible. Please avoid rapid transitions in ambient temperature, especially in high humidity environments where condensation can occur. -4-
6 (4) Recommended circuit In designing a circuit, the current through each LED must not exceed the absolute maximum rating specified for each LED. It is recommended to use Circuit B which regulates the current flowing through each LED. In the meanwhile, when driving LEDs with a constant voltage in Circuit A, the current through the LEDs may vary due to the variation in forward voltage (VF) of the LEDs. In the worst case, some LED may be subjected to stresses in excess of the absolute maximum rating. (A) (B) This product should be operated in forward bias. A driving circuit must be designed so that the product is not subjected to either forward or reverse voltage while it is off. In particular, if a reverse voltage is continuously applied to the product, such operation can cause migration resulting in LED damage. (5) Circuit Design For electrical design of the product, make sure that no voltage is applied to an LED while it is off. -5-
7 (6) Soldering Conditions The LEDs can be soldered in place using the reflow soldering method. Nichia cannot make a guarantee on the LEDs after they have been assembled using the dip soldering method. Recommended soldering conditions Reflow Soldering Hand Soldering Lead Solder Lead-free Solder Pre-heat Pre-heat time Peak temperature Soldering time Condition 120 ~ 150 C 120 sec. Max. 240 C Max. 10 sec. Max. refer to Temperature - profile ~ 200 C 120 sec. Max. 260 C Max. 10 sec. Max. refer to Temperature - profile 2. (N 2 reflow is recommended.) Temperature Soldering time 350 C Max. 3 sec. Max. (one time only) Although the recommended soldering conditions are specified in the above table, reflow or hand soldering at the lowest possible temperature is desirable for the LEDs. A rapid-rate process is not recommended for cooling the LEDs down from the peak temperature. [Temperature-profile (Surface of circuit board)] Use the conditions shown to the under figure. <1 : Lead Solder> <2 : Lead-free Solder> 2.5 ~ 5 C / sec. Pre-heating 2.5 ~ 5 C / sec. 120 ~ 150 C 60sec.Max. Above 200 C 240 C Max. 10sec. Max. 1 ~ 5 C / sec. Pre-heating 1 ~ 5 C / sec. 180 ~ 200 C 60sec.Max. Above 220 C 260 C Max. 10sec. Max. 120sec.Max. [Recommended soldering pad design] 120sec.Max. Use the following conditions shown in the figure (Unit : mm) Occasionally there is a brightness decrease caused by the influence of heat or ambient atmosphere during air reflow. It is recommended that the customer use the nitrogen reflow method. The encapsulated material of the LEDs is silicone. Therefore the LEDs have a soft surface on the top of package. The pressure to the top surface will be influence to the reliability of the LEDs. Precautions should be taken to avoid the strong pressure on the encapsulated part. So when using the chip mounter, the picking up nozzle that does not affect the silicone resin should be used. Repairing should not be done after the LEDs have been soldered. When repairing is unavoidable, a double-head soldering iron should be used. It should be confirmed beforehand whether the characteristics of the LEDs will or will not be damaged by repairing. Reflow soldering should not be done more than two times. When soldering, do not put stress on the LEDs during heating. After soldering, do not warp the circuit board. -6-
8 (7) Heat Generation Thermal design of the end product is of paramount importance. Please consider the heat generation of the LED when making the system design. The coefficient of temperature increase per input electric power is affected by the thermal resistance of the circuit board and density of LED placement on the board, as well as other components. It is necessary to avoid intense heat generation and operate within the maximum ratings given in this specification. The operating current should be decided after considering the ambient maximum temperature of LEDs. (8) Cleaning It is recommended that isopropyl alcohol be used as a solvent for cleaning the LEDs. When using other solvents, it should be confirmed beforehand whether the solvents will dissolve the package and the resin or not. Freon solvents should not be used to clean the LEDs because of worldwide regulations. Do not clean the LEDs by the ultrasonic. When it is absolutely necessary, the influence of ultrasonic cleaning on the LEDs depends on factors such as ultrasonic power and the assembled condition. Before cleaning, a pre-test should be done to confirm whether any damage to the LEDs will occur. (9) Static Electricity Static electricity or surge voltage damages the LEDs. It is recommended that a wrist band or an anti-electrostatic glove be used when handling the LEDs. All devices, equipment and machinery must be properly grounded. It is recommended that precautions be taken against surge voltage to the equipment that mounts the LEDs. When inspecting the final products in which LEDs were assembled, it is recommended to check whether the assembled LEDs are damaged by static electricity or not. It is easy to find static-damaged LEDs by a light-on test or a VF test at a lower current (below 1mA is recommended). The LEDs should be used the light detector etc. when testing the light-on. Do not stare into the LEDs when testing. Damaged LEDs will show some unusual characteristics such as the forward voltage becomes lower, or the LEDs do not light at the low current. Criteria :(VF > 2.0V at IF=0.5mA) (10) Safety Guideline for Human Eyes The International Electrical Commission (IEC) published in 2006 IEC 62471:2006 Photobiological safety of lamps and lamp systems which includes LEDs within its scope. Meanwhile LEDs were removed from the scope of the IEC :2007 laser safety standard, the 2001 edition of which included LED sources within its scope. However, keep in mind that some countries and regions have adopted standards based on the IEC laser safety standard IEC :2001 which includes LEDs within its scope. Following IEC 62471:2006, most of Nichia LEDs can be classified as belonging to either Exempt Group or Risk Group 1. Optical characteristics of a LED such as radiant flux, spectrum and light distribution are factors that affect the risk group determination of the LED. Especially a high-power LED, that emits light containing blue wavelengths, may be in Risk Group 2. Great care should be taken when viewing directly the LED driven at high current or the LED with optical instruments, which may greatly increase the hazard to your eyes. -7-
9 (11) Others NSSU100B complies with RoHS Directive. This LED also emits visible light. Please take notice of visible light spectrum, in case you use this LED as light source of sensors etc. The LEDs described in this brochure are intended to be used for ordinary electronic equipment (such as office equipment, communications equipment, measurement instruments and household appliances). Consult Nichia s sales staff in advance for information on the applications in which exceptional quality and reliability are required, particularly when the failure or malfunction of the LEDs may directly jeopardize life or health (such as for airplanes, aerospace, submersible repeaters, nuclear reactor control systems, automobiles, traffic control equipment, life support systems and safety devices). The customer shall not reverse engineer by disassembling or analysis of the LEDs without having prior written consent from Nichia. When defective LEDs are found, the customer shall inform Nichia directly before disassembling or analysis. The formal specifications must be exchanged and signed by both parties before large volume purchase begins. The appearance and specifications of the product may be modified for improvement without notice. -8-
10 順電圧 - 順電流特性 Forward Voltage vs. VfIf Forward Current 順電流 IFP (ma) Forward Current IFP (ma) 順電圧 VF (V) Forward Voltage VF (V) 順電流 - 相対放射束特性 デューティー比 - 許容順電流特性 Forward Current vs. IfIv Duty Ratio vs. Duty Ta=25 Ta=25 Ta=25 Relative Radiant Flux Allowable Forward Current 相対放射束 (a.u.) Relative Radiant Flux (a.u.) 順電流 IFP (ma) Forward Current IFP (ma) 許容順電流 IFP (ma) Allowable Forward Current IFP (ma) デューティー比 (%) Duty Ratio (%) 周囲温度 - 順電圧特性 Ambient Temperature TaVf vs. Forward Voltage IFP= 20mA 周囲温度 - 相対放射束特性 Ambient Temperature TaIv vs. Relative Radiant Flux IFP= 20mA 周囲温度 - 許容順電流特性 Ambient Temperature vs. Allowable Forward Current Derating -9- 順電圧 VF (V) Forward Voltage VF (V) 相対放射束 (a.u.) Relative Radiant Flux (a.u.) 許容順電流 IF (ma) Allowable Forward Current IF (ma) (50,25) (85,7.5) 周囲温度 Ta ( ) Ambient Temperature Ta ( ) 周囲温度 Ta ( ) Ambient Temperature Ta ( ) 型名 Model 周囲温度 Ta ( ) Ambient Temperature Ta ( ) NSSU100B 日亜化学工業 ( 株 ) NICHIA CORPORATION 名称 Title 管理番号 No. 初期電気 / 光学特性 CHARACTERISTICS
11 順電流 -ピーク波長特性 Forward Current IfλD vs. Peak Wavelength ピーク波長 λp (nm) Peak Wavelength λp (nm) Ta= 順電流 IFP (ma) Forward Current IFP (ma) 発光スペクトル Spectrum Spectrum 相対発光強度 (a.u.) Relative Emission Intensity (a.u.) 波長 λ (nm) Wavelength λ (nm) Ta=25 IF= 20mA -10- 周囲温度 -ピーク波長特性 Ambient Temperature TaλD vs. Peak Wavelength ピーク波長 λp (nm) Peak Wavelength λp (nm) IFP= 20mA 指向特性 Directivity 放射角度 Radiation Angle Directivity Ta=25 IFP= 20mA 70 X 80 X-X Y-Y Y Y X 周囲温度 Ta ( ) Ambient Temperature Ta ( ) 相対放射強度 (a.u.) Relative Radiant Intensity (a.u.) 型名 Model NSSU100B 日亜化学工業 ( 株 ) NICHIA CORPORATION 名称 Title 管理番号 No. 初期電気 / 光学特性 CHARACTERISTICS
12 ± Anode A 保護素子 Protection device LED chip K -11- Cathode mark 0.5 Cathode ( 注 ) 本製品には静電気に対する保護素子が内蔵されています (NOTE) NSSU100x has a protection device built in as a protection circuit against static electricity. 項目 Item パッケージ材質 Package 封止樹脂 Encapsulating Resin 電極 Electrodes 型名 Model NSSU100x 日亜化学工業 ( 株 ) NICHIA CORPORATION 材質 Materials セラミックス Ceramics シリコーン樹脂 Silicone Resin 金メッキ Au Plating 名称 Title 管理番号 No. 外形寸法図 OUTLINE DIMENSIONS 単位 Unit mm 公差 Allow ±0.2
13 テーピング部 Taping part Φ ±0.1 2 ± ± ±0.05 リール部 Reel part ±1 9 ±0.3 Cathode mark 3.5 ± ±0.2 Φ 21 ±0.8 Φ 13 ±0.2 Φ ±0.1 Φ MAX. ラベル Label トレーラ部 / リーダ部 Trailer Part/Leader Part 2.5 ±0.2 エンボスキャリアテープ Embossed carrier tape -12- 引き出し方向 Pull direction トレーラ部 Min.160mm( 空部 ) Trailer part Min.160mm (No LEDs) LED 装着部 LEDs mounting part 引き出し部 Min.100mm( 空部 ) Reel Lead Min.100mm(No LEDs) トップカバーテープ Top cover tape JIS C 0806 電子部品テーピング準拠 Taping is based on the : Packaging of Electronic Components on Continuous Tapes. 数量 2,500 個入 / リール Quantity 2,500pcs/Reel 型名 Model NSSU100xT 日亜化学工業 ( 株 ) NICHIA CORPORATION リーダ部 Min.400mm Leader part Min.400mm 名称 Title 管理番号 No. テーピング仕様図 TAPING DIMENSIONS 単位 Unit mm
14 シリカゲルとともにリールをアルミ防湿袋に入れ 熱シールにより封をする The reel and moisture absorbent material are put in the moisture proof foil bag and then heat sealed. アルミ防湿袋 Moisture proof foil bag リール Reel 熱シール Seal ラベル Label TYPE UV LED NSSU100xT LOT QTY. xxxxxx- PCS RoHS NICHIA CORPORATION 491 OKA, KAMINAKA, ANAN, TOKUSHIMA, JAPAN シリカゲル Moisture absorbent material 警告ラベル Caution Label 光学測定装置で直接観察してはならないクラス1M LED 製品 LED RADIATION DO NOT VIEW DIRECTLY WITH OPTICAL INSTRUMENTS CLASS 1M LED PRODUCT ダンボールで仕切りをする The box is partitioned with the cardboard. アルミ防湿袋 外箱に貼り付け This Caution Label is applied on Moisture proof foil bag and on Cardboard box. ラベル Label TYPE UV LED NSSU100xT Nichia LED RANK QTY. PCS RoHS NICHIA CORPORATION 491 OKA, KAMINAKA, ANAN, TOKUSHIMA, JAPAN 基本梱包単位 Packing Unit アルミ防湿袋 Moisture proof foil bag 梱包箱 ( 段ボール ) Cardbord box S M L リール数 Reel/bag 1reel 箱の寸法 Dimensions(mm) t t t チップ個数 Quantity/bag(pcs) 2,500 MAX. リール数 Reel/box 7reel MAX. 15reel MAX. 30reel MAX. チップ個数 Quantity/box(pcs) 17,500 MAX. 37,500 MAX. 75,000 MAX. 型名 Model NSSU100xT 日亜化学工業 ( 株 ) NICHIA CORPORATION 名称 Title 管理番号 No. 梱包仕様図 PACKING